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Online since: July 2014
Authors: Xiang Wei Fang, Chun Hai Li, Chun Ni Shen, Long Wang
Buffer/backfill material used in the construction of an underground repository is one of the important aspects, and the bentonite sand mixed buffer/backfill materials have become popular around the world.
Applied Clay Science,2009, (42):575-582
Journal of ggeotechnicail and geoenvironmental engineering,2004, 30(2): 205-209
Chinese Journal of Rock Mechanics and Engineering,2011, 30(2):382-390
Study on clay-based materials for the repository[J].
Applied Clay Science,2009, (42):575-582
Journal of ggeotechnicail and geoenvironmental engineering,2004, 30(2): 205-209
Chinese Journal of Rock Mechanics and Engineering,2011, 30(2):382-390
Study on clay-based materials for the repository[J].
Online since: September 2013
Authors: Sheng Wei Ma, Hai Gang Chen, Xiu Li Liao, Pi Mao Chen
Materials and methods
Study area
Six comprehensive surveys of ecological environment were carried out in April 2007, March, May, August, November 2008 and May 2009 in Yangmeikeng artificial reef area.
Baine: Ocean and Coastal Management, Vol. 44(3/4)( 2001), p. 241 [4] Shouyu Zhang, Huanjun Zhang, Junpeng Jiao, Risong Li, Kongwen Zhu: Journal of Fisheries of China, Vol. 30(4)(2006), p. 475 (in Chinese) [5] M.
Lindberg: Marine Ecology Progress Series, Vol. 264(2003), p. 265 [12] Pimao Chen: Journal of Tropical Oceanography, Vol. 24(3)(2005), p. 73 (in Chinese) [13] F.
Monteino: Marine Ecology, Vol. 29(4)( 2008), p. 435 [14] Zhenhua Wang, Shouyu Zhang, Kai Wang, Jing Zhao, Min Xu: Journal of Fisheries of China, Vol. 34(5)(2010), p. 751 (in Chinese) [15] Liu Yang, Shou Zhang, Manchang Sun, Hu Zhang: Journal of Shanghai Ocean University, Vol. 20(3)(2011), p. 445 (in Chinese) [16] Shuo Zhang, Kongwen Zhu, Manchang Sun: Journal of Dalian Fisheries University, Vol. 21(2)(2006), p. 134 (in Chinese) [17] Yinghua Chen, Huajie Wang, Yufeng Yang: Ecological Science, Vol. 27(5)(2008), p. 429 [18] Anping Lei, Huan Chen, Jufang Chen, Zhangli Hu: Ocean Technology, Vol. 28(4)(2009), p. 83 (in Chinese) [19] F.
Shaw: Journal of Natural History, Vol. 17(6)( 1983), p. 859 [22] Qingshan Luan, Jun Sun, Shuqun Song, Zhiliang Shen, Zhiming Yu: Journal of Plant Ecology(Chinese Version), Vol. 31(3)( 2007), p. 445 [23] Xiaoping Jia, Feiyan Du, Qin Lin, Chunhou Li, Wengui Cai: Journal of Fishery Sciences of China, Vol. 10(2)(2003), p. 160 (in Chinese) [24] Zhibing Jiang, Quanzhen Chen, Lu Shou, Yibo Liao, Xuyu Zhu, Yu Gao, Jiangning Zeng, Yuexia Zhang: Acta Ecologica Sinica, Vol. 32(18)(2012), p. 5813 (in Chinese)
Baine: Ocean and Coastal Management, Vol. 44(3/4)( 2001), p. 241 [4] Shouyu Zhang, Huanjun Zhang, Junpeng Jiao, Risong Li, Kongwen Zhu: Journal of Fisheries of China, Vol. 30(4)(2006), p. 475 (in Chinese) [5] M.
Lindberg: Marine Ecology Progress Series, Vol. 264(2003), p. 265 [12] Pimao Chen: Journal of Tropical Oceanography, Vol. 24(3)(2005), p. 73 (in Chinese) [13] F.
Monteino: Marine Ecology, Vol. 29(4)( 2008), p. 435 [14] Zhenhua Wang, Shouyu Zhang, Kai Wang, Jing Zhao, Min Xu: Journal of Fisheries of China, Vol. 34(5)(2010), p. 751 (in Chinese) [15] Liu Yang, Shou Zhang, Manchang Sun, Hu Zhang: Journal of Shanghai Ocean University, Vol. 20(3)(2011), p. 445 (in Chinese) [16] Shuo Zhang, Kongwen Zhu, Manchang Sun: Journal of Dalian Fisheries University, Vol. 21(2)(2006), p. 134 (in Chinese) [17] Yinghua Chen, Huajie Wang, Yufeng Yang: Ecological Science, Vol. 27(5)(2008), p. 429 [18] Anping Lei, Huan Chen, Jufang Chen, Zhangli Hu: Ocean Technology, Vol. 28(4)(2009), p. 83 (in Chinese) [19] F.
Shaw: Journal of Natural History, Vol. 17(6)( 1983), p. 859 [22] Qingshan Luan, Jun Sun, Shuqun Song, Zhiliang Shen, Zhiming Yu: Journal of Plant Ecology(Chinese Version), Vol. 31(3)( 2007), p. 445 [23] Xiaoping Jia, Feiyan Du, Qin Lin, Chunhou Li, Wengui Cai: Journal of Fishery Sciences of China, Vol. 10(2)(2003), p. 160 (in Chinese) [24] Zhibing Jiang, Quanzhen Chen, Lu Shou, Yibo Liao, Xuyu Zhu, Yu Gao, Jiangning Zeng, Yuexia Zhang: Acta Ecologica Sinica, Vol. 32(18)(2012), p. 5813 (in Chinese)
Online since: July 2020
Authors: Hayder Hussein H. Kammona, Muhammad Abed Attiya, Qasim M. Shakir
In such situations, there may be a partial change in materials or enlargement in cross-section of some members beyond the initial stage of loading.
Properties of steel bars and CFRP [10] Type of material Modulus of elasticity [GPa] Yield stress [(MPa] Yield strain Ultimate Strain Ultimate stress [MPa] Bar diameters (mm) 6 197 450 0.00228 --- 550 18 198 520 0.00262 --- 620 CFRP sheets 180 --- -- 0.01 1650 Materials and Finite Element Simulation.
Journal of Engineering Research and Application, 6 (2016) 1-5
Abdel-Jawad Retrofitting of Reinforced Concrete Beams Using Composite Laminates, Construction & Building Materials, 25 (2011) 591-597
Zhang, FEM Analysis of EDM in Gas Based on Birth and Death of Element, Materials Science Forum, 626 (2009) 599-604
Properties of steel bars and CFRP [10] Type of material Modulus of elasticity [GPa] Yield stress [(MPa] Yield strain Ultimate Strain Ultimate stress [MPa] Bar diameters (mm) 6 197 450 0.00228 --- 550 18 198 520 0.00262 --- 620 CFRP sheets 180 --- -- 0.01 1650 Materials and Finite Element Simulation.
Journal of Engineering Research and Application, 6 (2016) 1-5
Abdel-Jawad Retrofitting of Reinforced Concrete Beams Using Composite Laminates, Construction & Building Materials, 25 (2011) 591-597
Zhang, FEM Analysis of EDM in Gas Based on Birth and Death of Element, Materials Science Forum, 626 (2009) 599-604
Online since: August 2015
Authors: Sisa Pityana, Peter Apata Olubambi, Babatunde A. Obadele, Mathew Thoppil Mathew, Anthony Andrews
Kobayashi, Materials Science and Engineering: A, 160 (1993) 143-153
Man, Materials Science and Engineering: A, 392 (2005) 348-358
Man, Materials Science and Engineering: A, 402 (2005) 126-134
Pathak, Materials Science and Engineering: C, 48 (2015) 243-255
Bandyopadhyay, Journal of the Mechanical Behavior of Biomedical Materials, 32 (2014) 335-344
Man, Materials Science and Engineering: A, 392 (2005) 348-358
Man, Materials Science and Engineering: A, 402 (2005) 126-134
Pathak, Materials Science and Engineering: C, 48 (2015) 243-255
Bandyopadhyay, Journal of the Mechanical Behavior of Biomedical Materials, 32 (2014) 335-344
Online since: December 2012
Authors: Yang Liao, Gong Long Liu, Wei Min Shi, Lei Ma, Wei Guang Yang, Yue Lu Zhang
Growth Time Influence on Polycrystalline α-HgI2 Films
Gonglong Liu1,a, *, Lei Ma2,b, Yang Liao1,c , Weimin Shi 1,d , Weiguang Yang1,e, Yuelu Zhang1,f
1Department of Electronic Information Materials, School of Materials Science and Engineering, Shanghai University, Shanghai 200072, China
2The eighth design department of the Shanghai Aerospace Bureau, Shanghai Institute of Mechanical and Electrical Engineering, Shanghai 200233, China
aliugonglong@shu.edu.cn, bmalei888@shu.edu.cn,csunny1172@shu.edu.cn,
d wmshi@mail.shu.edu.cn, ewgyangd@gmail.com , fzyl200612316@126.com
Keywords: Vapor phase deposition, Characterization, α-HgI2 films, Uniformity
Abstract.
Introduction Mercuric iodide (HgI2), an excellent photoconductor material, has been regarded as a leading material for nuclear radiation detectors working at room temperature, because of its high theory resistivity (1013Ω·cm), high atomic numbers (Hg=80, I=53), wide energy band gap (Eg=2.13eV), big absorption cross section and low electron-hole pair creation energy of 4.2 eV at room temperature[1-3].
Acknowledgements The authors gratefully acknowledge the financial support of the project from the National Science Foundation of China (Grant No. 10775096), China Postdoctoral Science Foundation (No. 20100480579), Nature Science Foundation of Shanghai (No. 06ZR14035) and Shanghai Leading Academic Disciplines (T0101).
[6] G .Zentai, L .Partain, R .Pavlyuchkova, Comparison of mercuric iodide and lead iodide X-ray detectors for X-ray imaging applications.IEEE Transactions on Nuclear Science, Vol.53(2006): p.2506
"Comparison of PbI2 and HgI2 for direct detection active matrix x-ray image sensors, "Journal of Applied Physics, Vols.91(2002)p.3345-3355 [8]J.B.
Introduction Mercuric iodide (HgI2), an excellent photoconductor material, has been regarded as a leading material for nuclear radiation detectors working at room temperature, because of its high theory resistivity (1013Ω·cm), high atomic numbers (Hg=80, I=53), wide energy band gap (Eg=2.13eV), big absorption cross section and low electron-hole pair creation energy of 4.2 eV at room temperature[1-3].
Acknowledgements The authors gratefully acknowledge the financial support of the project from the National Science Foundation of China (Grant No. 10775096), China Postdoctoral Science Foundation (No. 20100480579), Nature Science Foundation of Shanghai (No. 06ZR14035) and Shanghai Leading Academic Disciplines (T0101).
[6] G .Zentai, L .Partain, R .Pavlyuchkova, Comparison of mercuric iodide and lead iodide X-ray detectors for X-ray imaging applications.IEEE Transactions on Nuclear Science, Vol.53(2006): p.2506
"Comparison of PbI2 and HgI2 for direct detection active matrix x-ray image sensors, "Journal of Applied Physics, Vols.91(2002)p.3345-3355 [8]J.B.
Online since: June 2017
Authors: Suejit Pechprasarn, Supannee Learkthanakhachon, Manas Sangworasil, Naphat Albutt, Michael G. Somekh
Somekh1,d and Naphat Albutt3,e*
1Department of Electronic and Information Engineering, the Hong Kong Polytechnic University, Hong Kong SAR, China
2Biomedical Engineering Program, Department of Physics, Faculty of Science, Rangsit University, Pathum Thani, Thailand
3Division of Industrial Materials Science, Faculty of Science and Technology,
Rajamangala University of Technology Phra Nakhon, Bangkok 10800, Thailand
asupannee.learkthanakhachon@polyu.edu.hk , bsuejit.pechprasarn@polyu.edu.hk, cksamanas@gmail.com ,dmike.somekh@polyu.edu.hk , enaphat.cha@rmutp.ac.th
Keywords: Surface plasmon resonance, ultrasound sensor, acoustic, acousto-optic
Abstract.
Material Thickness Refractive index Water - 1.3300 Au 53 nm 0.1283+j3.9815 Cr 1 nm 3.9891+j4.1849 N-BK7 170 µm 1.51 Acoustic simulation The acoustic field profile was simulated using COMSOL to determine the maximum pressure at the metal/water interface as the acoustic wave incidents on the SPR sensor.
The authors also thank to Department of Electronic and Information Engineering, the Hong Kong Polytechnic University, Hong Kong SAR, China and the division of Industrial Materials Science, Faculty of Science and Technology, Rajamangala University of Technology Phra Nakhon (RMUTP).
Sigrist, Laser generation of acoustic waves in liquids and gases, Journal of Applied Physics, vol. 60, no. 7, p.
Zayats, Ultrasensitive Non-Resonant Detection of Ultrasound with Plasmonic Metamaterials, Advanced Materials, vol. 25, no. 16, pp. 2351–2356, Mar. (2013) [9] P.
Material Thickness Refractive index Water - 1.3300 Au 53 nm 0.1283+j3.9815 Cr 1 nm 3.9891+j4.1849 N-BK7 170 µm 1.51 Acoustic simulation The acoustic field profile was simulated using COMSOL to determine the maximum pressure at the metal/water interface as the acoustic wave incidents on the SPR sensor.
The authors also thank to Department of Electronic and Information Engineering, the Hong Kong Polytechnic University, Hong Kong SAR, China and the division of Industrial Materials Science, Faculty of Science and Technology, Rajamangala University of Technology Phra Nakhon (RMUTP).
Sigrist, Laser generation of acoustic waves in liquids and gases, Journal of Applied Physics, vol. 60, no. 7, p.
Zayats, Ultrasensitive Non-Resonant Detection of Ultrasound with Plasmonic Metamaterials, Advanced Materials, vol. 25, no. 16, pp. 2351–2356, Mar. (2013) [9] P.
Online since: February 2016
Authors: Jozef Peterka, Ivan Buranský, Vladimír Šimna, Tomáš Vopát
The results show different achieved surface roughness of machined material C45 and tool life of ball nose end mills depending on the copy milling strategy for various tool materials.
Materials and Methods Workpiece Material: The selected workpiece material was medium-carbon steel of ISO C45 (AISI 1045) grade.
The tested cutting tool materials were uncoated cemented carbide (MicroGrain) and high speed steel (HSS-Co5).
Tonshoff et al. [8] found that the optimum inclined angle is 15° for ball end-milling of block materials.
Hernandez-Camacho, Die manufacturing by 5 and 3 axes milling, Journal of Mechanical Working Technology 20 (1989) pp. 105-119
Materials and Methods Workpiece Material: The selected workpiece material was medium-carbon steel of ISO C45 (AISI 1045) grade.
The tested cutting tool materials were uncoated cemented carbide (MicroGrain) and high speed steel (HSS-Co5).
Tonshoff et al. [8] found that the optimum inclined angle is 15° for ball end-milling of block materials.
Hernandez-Camacho, Die manufacturing by 5 and 3 axes milling, Journal of Mechanical Working Technology 20 (1989) pp. 105-119
Online since: August 2019
Authors: Vaibhav Sonkar, Somnath Bhattacharya, Kamal Sharma
Functionally Graded Materials are referred as the composite materials.
The composition and microstructure of the constituent materials change in FGM.
Results reveal that the value of SIF in FGM is less than that of its constituent materials.
Mishra, “Mixed-mode fatigue crack growth analysis of functionally graded materials by XFEM,” Int.
Mishra, “International journal of mechanical sciences fatigue life simulation of functionally graded materials under cyclic thermal load using XFEM,” Int.
The composition and microstructure of the constituent materials change in FGM.
Results reveal that the value of SIF in FGM is less than that of its constituent materials.
Mishra, “Mixed-mode fatigue crack growth analysis of functionally graded materials by XFEM,” Int.
Mishra, “International journal of mechanical sciences fatigue life simulation of functionally graded materials under cyclic thermal load using XFEM,” Int.
Online since: October 2006
Authors: Gook Hyun Ha, Hyun Woo Lee, Ji Hun Yu, Myung Hee Lee, Kong Hoon Lee, Seung Woo Han
The fabrication process
of the thermoelectric materials has been discussed.
Bi-Sb-Te Thermoelectric Materials Fabrication Process.
The typical materials 20%Bi2Te3 + 80%Sb2Te3 for p-type and 95%Bi2Te3 for n-type thermoelectric materials are selected in this study.
The mechanical properties of the materials were obtained using the nanoindentation method.
Maahn: Recent Trends in Thermoelectric Materials Vol.
Bi-Sb-Te Thermoelectric Materials Fabrication Process.
The typical materials 20%Bi2Te3 + 80%Sb2Te3 for p-type and 95%Bi2Te3 for n-type thermoelectric materials are selected in this study.
The mechanical properties of the materials were obtained using the nanoindentation method.
Maahn: Recent Trends in Thermoelectric Materials Vol.
Online since: December 2024
Authors: T. Surya, K Supraja, G. Sai Kumar, A. Vignesh, T. Nikhil, E. Narasimhulu
The results of this study should add to our understanding of environmentally friendly building materials, especially as it relates to concrete manufacturing.
Materials Cement: Cement is a crucial binding agent used in construction and building materials to create concrete, mortar, and other applications.
Fineness of cement 3% Fine aggregate Fine aggregate, in the context of construction materials, refers to granular materials that pass through a sieve with a nominal maximum size of 4.75 millimetres (No. 4 sieve).
References [1] Ajithaa V, SasiRega M, Gowrishankar R- “A Study on Concrete Incorporated with Zeolite and Fly Ash”, International Journal of Research in Engineering and Science (IJRES) Volume 11 Issue 5, May 2023, PP. 810-814
Construction and Building Materials, 13: 427 – 432”
Materials Cement: Cement is a crucial binding agent used in construction and building materials to create concrete, mortar, and other applications.
Fineness of cement 3% Fine aggregate Fine aggregate, in the context of construction materials, refers to granular materials that pass through a sieve with a nominal maximum size of 4.75 millimetres (No. 4 sieve).
References [1] Ajithaa V, SasiRega M, Gowrishankar R- “A Study on Concrete Incorporated with Zeolite and Fly Ash”, International Journal of Research in Engineering and Science (IJRES) Volume 11 Issue 5, May 2023, PP. 810-814
Construction and Building Materials, 13: 427 – 432”